Method and Device for Applying Fluids

ABSTRACT

This document describes a process and a device for applying fluids, specifically particle material, on an area to be coated, which is viewed in forward moving direction of the coater, that fluid is applied on the area to be coated and then a levelling element is run over the applied fluid, whereby the fluid is led from a metering system provided with an opening, which oscillates when applying the fluid. The opening shall be designed in such a way that when the metering system is at a standstill this is closed by forming an angle of repose of the fluid.

This invention refers to a process and a device for applying fluids,especially particle material, on an area to be coated in accordance withthe preamble of claims 1 and 6. Furthermore the invention also concernsthe application of a device and a process like this.

The PCT publication script WO 35/18715 states to use a coater for theparticle material, designed in form of a downward opening funnel, in aprocess for manufacturing three-dimensional objects out of particlematerial, such as a rapid prototyping process. This funnel vibratesduring the coating process at right angles to the coater's direction ofmovement and parallel to the coating level. With a coater, as describedin this document, an unimpeded emission of the particle material duringcoating can be guaranteed and densification can be achieved.

But this type of coating has a disadvantage. The particle emissioncannot be switched, which means that when the vibration mechanism isdeactivated, powder escapes the coater, unless this is closed frombelow.

It is also known from DE 102 16 013 A1 that in the case of a process tomanufacture three-dimensional objects from particle material for theapplication of particle material, one container opened from the base,connected with a vibrating levelling element is used.

A significant advantage of this device is that the powder emission iscontrolled. The width of the gap is set so that when the coater isinactive, the powder is prevented from emission due to the particlebridges formed over the gap and the particle material only leaves thegap when the coater oscillates.

For very fine or/and very free flowing (fluid) powder materials, forexample fluids with a particle size <150 μm or powder, which mostlyconsists of round particles, this coating proves itself to be verycomplex because the gap has to be chosen very fine in order to achieve aspread of the particle material when the coater is inactive, becausesuch materials are less likely to form particle bridges.

This requires an accurate alignment of the gap width to achieve theeffect of the named invention. Moreover a constant gap width isnecessary over the entire width of a coater. This requires a veryprecise alignment. For production reasons this is either barely possibleor very costly.

This invention is challenged with providing a process, a device as wellas a use of the device with which a controlled metering and applicationof any and therefore also fine and/or free flowing powder is possible.

According to the invention this challenge is solved with a process toapply fluids, especially particle material, on an area to be coated,this being viewed in a forward moving direction of the coater, thatfluid is applied on the area to be coated and then a levelling elementis run over the applied fluid, whereby the fluid is led from a meteringsystem provided with an opening, which at least performs an oscillationduring application of the fluid. The opening is closed when the meteringsystem is at a standstill by the fluid forming an angle of repose in theopening.

The metering system features an oscillating container provided with anopening, in which the opening is designed in such a way that no materialflows out when the metering system is inactive as an angle of repose isformed in the opening and when the vibration mechanism is activated theangle of repose breaks downs and the particle material is emitted.

The levelling element can be designed as a blade, which is either runonly fixed over the fluid or also oscillates, if necessary, with themetering system.

Under the forward motion of the blade the direction of the coater shallbe recognised in the coating stage. If coating is possible in two ormore directions of the coater, the forward motion can also be possiblein several directions.

As a levelling element a roller with an axle parallel to the surfacearea to be coated and vertical to the coating direction is also suited.The roller can be fixed, or rotate around its own axle. The direction ofrotation is set in the opposite direction to the forward motiondirection of the coater, in order to emit the fluid from the gap betweenroller and powder bed surface.

The fluid is coated according to this invention from a metering systemprovided with an opening, whereby the opening, described in theillustration, is designed in a vertical direction to the area to becoated seen with an angle α. In colloquial speech it is a type of “side”opening. No vertical application is made on the area to be coated.

The opening is blocked from particle material when the container isinactive due to the formation of an angle of repose in the opening. Itno longer flows uncontrolled, as in processes of prior art, when thecoater is at a standstill. Instead it is retained by the design of theopening according to the invention when the coater is at a standstill.

The opening can have any width adapted to the process. If a componentessentially spans across the entire width of the area to be coated, thecoater and the opening also span over their entire width favourably. Oneand/or several smaller openings would also be possible.

The oscillation of the metering system can be horizontal or/and verticalaccording to this invention. Especially good results could be achievedif the oscillation contains vertical as well as horizontal components.In particular an oscillation proved itself to be beneficial according tothe type of rotation.

Especially good coating results could be achieved with a process in linewith the invention, if the levelling element also oscillates when theapplied fluid runs over. In the case of an especially preferred theembodiment of this invention the levelling element resonates with themetering system.

In such an embodiment of this invention the densification of the fluidcan be achieved by two effects.

By means of the oscillation or vibrations of the container and thefluid, the particles of the material to be coated are graded to a higherpacking density. In addition if the levelling element oscillateshorizontally and/or vertically, a densification of the fluid under thelevelling element is also achieved through movement.

However, it must be observed that too strong a densification of theparticle material achieved this way can lead to movement in the powderbed over the actual layer and thus lead to a deterioration of thestructure printed.

According to this invention, the particle material is compacted by theoscillation prior to coating in the metering system, so before layingthe coat, the densification can be carried out gently by the levellingelement. Damage to the area to be coated is therefore avoided.

The densification of the powder bed is essentially homogenous over thearea to be coated and not dependent on the direction of the coater, asthis Is the case In the process of the prior art. It is possibletherefore to achieve an adequately good coating result in one coat. Thisleads to a time saving compared to the process of prior art, with whichan adequately homogenous coating result only can be achieved typicallyafter a second coat.

If it requires further definition of the rapid prototyping equipment,the coater and as the case may be, the metering system can be led backover the powder bed into the starting position after running over thearea to be coated once, at increased speed and without oscillation andtherefore without particle emission. The coating result achievedpreviously is thus not affected.

According to a favoured embodiment of this patent a metering quantity offluid required for the coating should always be smaller than residualvolume of the fluid present in the container.

By means of oscillation of the metering system, and the container if thecase may be, the fluid can be metered on the area to be coated. Whenactivating the oscillation mechanism of the container the fluid, and ifthe case may be the particle material, is fluidised in the container andflows out of the opening of the metering system in front of thelevelling element. If the oscillation mechanism stops, when an angle orrepose is formed in the opening the particle material remains in thecontainer.

The rotary motion of the coater's oscillation, the metering systemand/or the levelling element is preferably achieved over the eccentricfor the process in line with the invention, which are attached torqueproof to the drive motor shaft.

The transmission of power from the eccentric to the coater, the meteringsystem or/and the levelling element can be for example, form-fit,therefore illustrated by directly applying a ball bearing on theeccentric.

This process in line with the invention can be carried out preferablywith a device to apply fluids on an area to be coated, whereby alevelling element and a metering device viewed in forward direction ofthe levelling element is provided, via the fluid to be applied on thearea to be coated. The blade can be run over the fluid applied, wherebythe metering device is provided with an opening and an oscillation canbe performed. The opening is designed in line with this device, in sucha way that when the metering system is at a standstill it is closed bymeans of the fluid forming an angle of repose.

In accordance with the preferred embodiment the device is designed insuch a way that the metering system, and the container respectively isconnected to the levelling element.

With such a preferred embodiment of the invention it is possible toplace the emission of particle material as close as possible on thelevelling element. Furthermore it is also possible that the oscillationmechanism as well as the metering system also drives the levellingelement.

In line with an especially preferred embodiment the container of themetering system is essentially designed as a funnel.

In activating the oscillation mechanism of the container, so the funnelhere, the particle material fluidises in the funnel and flows out of theside opening, which can be designed as a gap, in front of the levellingelement.

In another case the particle material stays in the container, if the gap(length and height) is set accordingly, so that due to the formation ofan angle of repose in the opening other material is prevented fromemission. The funnel can therefore convey a significantly largerquantity of material than is necessary for the actual coat.

On the one hand the result is a significantly lower quantity of wastematerial. On the other hand the requirements of the feed system, whichmeters the particle material Into the funnel, are reduced. An equaldistribution of quantity in the container over the coater width or thewidth of the opening has to be ensured.

A possible over-filling or if the supply is lowered too heavily into thefunnel could be monitored preferably with a fill level sensor and ifnecessary, it would be possible to top up the funnel from the feedsystem. This is possible after one coat.

The coating unit shall be designed as rigid as possible In order to beable to transfer the oscillations exactly.

The container opening, preferably a gap, shall be dimensioned in heightand length so that when the coater is inactive no particle materialflows out of the container or funnel and when the vibration mechanism isactivated just as much material is emitted as is necessary for coating.The emission quantity is preferably regulated via the gap height andoscillation amplitude of the metering system.

It has thus emerged that a longer gap has to be chosen higher, in orderto achieve the same material emission as a shorter gap. In order toachieve an equal emission over the entire coating width, it is useful tochoose a long and high gap. In this way the metering system is easier toset, more tolerant compared to variations in the gap dimension and moreunsusceptible to blockage of the gap.

If the gap is set too large, particle material is accrued in front ofthe blade during operation of the coater. In order to obtain a goodcoating result the quantity in front of the levelling element shouldremain constant during the entire coating process.

In a preferred embodiment this is therefore achieved so that the gap isfixed as close as possible over the surface area to be coated directlywith the levelling element. The gap can be dimensioned in a way thatwhen the vibration mechanism is activated relatively a great deal ofparticle material is emitted. In the coating the particle material isaccrued until it reaches the metering opening. Through the accruedparticle material now further material is prevented from escaping thesupply through the opening. In this way a constant quantity of powdercan be achieved in front of the levelling element without adjustmentworks on the gap height.

A self-regulating system like this has a significant advantage comparedto well-known coating process, as no exact alignment of the opening isnecessary. This is very complex particularly with very wide openings.

The levelling element smoothes and condenses the applied material. Achangeable blade is preferably chosen with a specific support length,via the incline of the support area to the coating surface area thedensification of the layer can set well.

The blade has rounded edges in accordance with a preferred embodiment.This prevents damage to the applied coating surface area. The roundforms preferably have a radius of 0.2 to 1 mm.

The coater, which at least consists of a metering system and thelevelling element, is activated to oscillate. One advantage is that theoscillation occurs mainly in the coating direction. However it is alsopossible to let the system oscillate with an additional verticalcomponent, in order to achieve a higher densification of the particlematerial. But is must be observed that too strong a densification of theparticle material can lead to a movement in the powder bed over theactual layer and thus lead to a deterioration of the structure printed.

Via the frequency and amplitudes (horizontal and vertical) of theoscillator, on the one hand the densification and on the other hand theemission quantity of the metering system can be set.

As already discussed the coating equipment in line with the invention isespecially suited for the use of very fine particle materials (particlesizes <150 μm) , as they are used in the current rapid prototypingprocesses, like 3D printing or selective laser sintering established forexample from the EP 0 431 924. In these processes the grain size of theparticle material determines the possible layer thickness and thereforethe accuracy and resolution of the printed parts.

Unlike the processes of prior art particle materials with rounded grainsizes and therefore high flow capability as well as powder withsquare-edged particles and lower flow capability can be processed. Bymeans of fluidisation of the particle material in the metering systemthe outcome in both cases is a homogenous coating result.

With the process according to the invention plastic particle materialssuch as PMMA, PA or PS, the most diverse forms of metal powder as wellas form sands such as silica sand, zircon sand, magnetite or chromerzsand can be processed. The selection of material grade depends solely onthe selected layer build method and the properties of the targetmaterial grade.

The particle materials can be homogenous or as particle mix or coatedpowder. It is also possible that other substances in the form of fluidsare added to the particle material before the coating process.

Other powder mixes contain for example fibre materials for laterstrengthening of the component.

Other beneficial embodiments of this invention result from the subclaims as well as the description.

For a more detailed illustrated the invention is described in moredetail below based on favoured design examples with reference to thediagram.

The diagram shows:

FIG. 1 the sequence of a process in line with the invention according toa preferred embodiment; and

FIG. 2 the device as per the invention in accordance with a preferredembodiment.

For example, below the process and the device according to the inventionfor use in layer design of cast models from particle material andbinding agent in rapid prototyping process are explained.

In particular it can be assumed from very fine and flow-capable particlematerials that a rapid prototyping process is used.

Referring to FIG. 1 the sequence of the coating is described belowaccording to the preferred, embodiment of the process in line with theinvention.

In a set up process of a component, such as for example a cast model, aconstruction platform 4 on which the model is to be built, is loweredaround a layer strength of the particle material 5. Then the particlematerial 5, for example very fine plastic powder is applied to theconstruction platform 4. This has a required layer strength from thecontainer, here a funnel 3. Then the selective application of bindingagent Is attached to one hardened areas. This can be carried out using adrop-on-demand-drop generator, depending on the type of ink-jet printer.These application steps are repeated, until the finished component,embedded into the loose particle material 5, is obtained.

At the start coater 1 is in the starting position, which is representedin FIG. 1 a. It Is first filled via a filling device, if the fill levelsensor has recognised a sub level In a container, which is designed hereas a funnel 3.

As illustrated in FIG. 1 b, the construction platform 4 is lowered tomore than one layer.

Then the coater 1, as shown in FIG. 1 c, without oscillation movementand thus without feed effect in the position compared to the fillingdevice 2, until it is over the edge of the construction platform 4.

Now the build platform 4 is raised exactly to the layer height, as FIG.1 d shows. This means that the build platform 4 is now accuratelylowered to the layer height.

Now the coater 1 begins to oscillate and goes in a constant run over thebuild platform 4. Thus it emits particle material 5 in exactly the rightquantity and coats the build platform 4. This is shown in FIG. 1 e.

The running speed of the coating is between 10 and 200 mm/s. Theselectable coating speed depends on the emitted particle quantity andthe movement of the individual particle. If the run speed is selectedtoo great compared to the particle emission, imperfections (surfacedetects) are formed in the powder bed, which can lead to delaminating ofthe component in the worst case. Generally for reasons of productivityhigher coating speeds are beneficial.

An unfavourable conformation of run speed in oscillation movement of thelevelling element leads to so-called chatter marks on the powder bedsurface. These have a negative effect on the component quality.Generally, the higher the coating speed chosen, the higher theoscillation frequency on the moved levelling element.

The coater 1 runs after the coating run without oscillation movement,which means as quick as possible, back to the starting position and canbe refilled as required via the filling device 2. This is shown in FIG.1 f, which corresponds to 1 a.

In order to balance an unequal filling of the coater 1 via its length,after a specific time the funnel 3 can be emptied via the wastercontainer 6 by means of oscillation of the funnel 3 and subsequentlyrefilled.

The printing process, or illumination process to harden the particlematerial provided with binding agent 1 can take place during or afterthe coating.

FIG. 2 shows a device In line with the invention according to a favouredembodiment.

In particular also for carrying out the process according to theinvention a device is suitable according to the demonstrated favouredembodiment.

In line with FIG. 2 particle material 5 is applied to an area to becoated, whereby a rocker 7, which contains a metering device 3, viewedin a forward direction 16 of the blade 14 particle material 5 on thebuild platform 4. Furthermore a blade 14 is provided as a levellingelement, which condenses, smoothes the applied material, and ensures aconstant layer thickness H_(s) of the applied particle material 5.

The rocker 7 is applied to the coater main bracket 10 according to thepreferred embodiment in such a way that it can perform an oscillationdepending on the type of rotary motion indicated by arrow 8. The coatermain bracket 10 spans over the entire width of the build platform 4 inaccordance with the preferred embodiment. The rotary axis 9 of therocker 7 is vertical to the running movement represented by arrow 16 inaccordance with the preferred embodiment and parallel to thelongitudinal axis of the rocker 7.

In this case the metering device 3 contains a container, a funnel-shapedparticle device, which is formed via the rocker 7 and a correspondingsheet 17, and features a metering gap, located in the container, whichresembles the shape of a funnel, sideways, which means vertical to thecoating direction viewed with an angle α and In running direction infront and above the stripper blade 14. In accordance with the diagramthis is about 90°. This shall only serve as an example.

The sheet 17 and the blade 14 are arranged in such a way that the gapheight H and gap length L of the opening 11 designed as a gap ismeasured so that when the vibration mechanism is deactivated no particlematerial 5 leaves the supply and when the vibration mechanism isactivated more particle material 5 is emitted than is necessary fordimension of the compressed layer. The height of the gap 11 can be setby means of the locking bolt 18.

The surplus material is collected in front of the blade 14. If thesurplus particle material 5 reaches the opening 11 in front of the blade14, which is formed here as a gap, further particle material 5 isprevented from leaving the opening 11. This way in the coating run alongthe blade 14 an equally large accumulation of particle material 5 is setin front of the blade. This leads to a uniform coating result over theentire width of the coater and over the entire length of the section 4.

The rocker 7 with the firmly connected or contained metering unit andblade 14 oscillates according to arrow 8 around the rotary axis 9 . Bymeans of another arrangement of the rotary axis 9 a movement can berealised with an additional vertical share, in order to achieve anadditional compression effect of the applied layer through an extravertical movement of the blade 14.

The oscillation of the rocker 7 can be set by the size of the eccentric12 and its juncture 19 with the rocker 7, so that the amplitude ofmovement of the blade 14 lies between 0.05 and 1 mm.

The amplitude and frequency of the oscillation are adapted so that thereis a sufficient compression of the particle layer and adequate particlematerial 5 is supplied by the metering system. The amplitude and theoscillation direction shall be chosen so that no damage to the areabelow the layer occurs.

The device is designed according to the embodiment in a way that apropulsion of the coater 4 is made over at least a fast running electromotor, which brings the wave 7 to oscillation via an eccentric.

The motor used for driving the eccentric 12 has for example a nominalrotation speed at 12V of 3000 U/min, the hub of the eccentric 12 amountsto 0.15 mm, which corresponds to an amplitude on the top of the blade 14of 0.20 mm according to the example described. At 15 V a rotationalspeed of 4050 U/min was measured. This value corresponds to 67.5 Hz.Depending on the width of the blade 7 It can be necessary, to provideseveral pivotal points.

The blade 14 features rounded edges. This prevents damage to the appliedcoating surface area. The round forms preferably have a radius of 0.2 to1 mm.

1-18. (canceled)
 19. A process for the application of a fluid includinga particle material, comprising the steps of: a) metering a fluidthrough an opening in a metering system; b) oscillating the meteringsystem while the fluid is being metered; c) levelling the applied fluidand d) closing the opening in the metering system when the meteringsystem is at a standstill by an angle of repose of the fluid.
 20. Theprocess of claim 19, wherein the oscillating step includes horizontaloscillating, vertical oscillating, rotational oscillating or anycombination thereof.
 21. The process of claim 19, wherein the step ofleveling is performed using a blade that oscillates with the meteringsystem.
 22. The process of claim 19, wherein the step of levelling isperformed by a rotating roller.
 23. The process of claim 19, wherein theamount of fluid being metered is smaller than a residual amount of fluidin the metering system.
 24. The process of claim 19, wherein theoscillating is performed by eccentric driven rocker.
 25. The process ofclaim 20, wherein the step of leveling is performed using a blade thatoscillates with the metering system.
 26. The process of claim 20,wherein the step of levelling is performed by a rotating roller.
 27. Theprocess of claim 25, wherein the oscillating is performed by eccentricdriven rocker.
 28. The process of claim 26, wherein the oscillating isperformed by eccentric driven rocker.
 29. A device for applying a fluidincluding a particle material, comprising: a) an oscillatable rockerhaving an external wall; b) an inclined sheet opposite the rockerexternal wall, c) a container for receiving the fluid defined by theexternal wall of the rocker and the inclined sheet, the containerincluding a vertically disposed opening; and d) a leveling element,wherein in operation, upon coming to a standstill, the opening is closedby an angle of repose of the fluid.
 30. The device of claim 29, furthercomprising an eccentric in driving relationship with the oscillatablerocker.
 31. The device of claim 29, wherein the inclined sheet isattached to the leveling element.
 32. The device of claim 29, whereinthe leveling element includes a blade.
 33. The device of claim 32,wherein the blade includes rounded edges having a radius of 0.2 to 1 mm.34. The device of claim 29, further comprising means for adjusting thesize of the opening.
 35. The device of claim 30, wherein the inclinedsheet is attached to the levelling element
 36. The device of claim 35,wherein the leveling element includes a blade.
 37. The device of claim36, further comprising means for adjusting the size of the opening. 38.The device of claim 30, wherein the eccentric is driven by an electricmotor.